DE4302249C2 - Graphic emulation process for a page printer - Google Patents

Description

The invention relates to a graphic emulation method for a page printer that uses a tape buffer system.

From DE-PS 38 05 573 and JP-OS'n 1-237 162 and 2-43067 are procedures and control systems for controlling printing operations known from a page printer to which image data are fed, which are intended for a dot matrix printer. Because the pressure dot density of a dot matrix printer is usually lower than that of a page printer, the image data are suitable ter transformed to print quality in the page printer improve.

The object of the invention is to create an emulation process with which to be used with a dot matrix printer Image data thus transformed for use in a page printer can be a bold overprint as well as filling in empty spaces can be achieved without that additional space is required and the process processing time for the image data to be reshaped becomes longer.

In an emulation process, this task is performed by the Features specified claim 1 solved.

In general, input image data is used in a dot matrix printer directly as image data for use in a page printer without filtering in the Page printer is made.

Fig. 5 shows a method for forming printing fonts of the image data in a dot matrix printer with eight pens. In order to form fonts of the dot matrix image data for the unit of a line in the page printer, the position of bits of the dot matrix image data is checked as shown in Fig. 6 so that line segments are formed as in Fig. 7 ge shows. The line segments are stored in a frame buffer in a full buffer system. The full buffer system brings data page by page into a memory in the form of a two-dimensional field. The memory stores character image data, graphic image data, and the like in response to control commands in the printer, and transfers the contents of the buffer to a print engine by a page output control command. In the tape buffer system, the line segments are stored in a symbolic buffer 402 of FIG. 8. The symbolic buffer 402 is generally in the form of a linked list, as shown in FIG. 8.

However, since there are no filtering operations when receiving the image data regardless of the image data form, various ineffective aspects occur when converting to a different printing method when overwriting, filling in spaces, etc. are used to make a clear one in a dot matrix printer Get picture. When overwriting or overprinting is used in the dot matrix printer, when the control input is "test print", bold is obtained by printing the print fonts multiple times in the same position as shown in Fig. 9. However, with a page printer that cannot control the density difference of printing dots (i.e. whether a dot is printed or not), the processing time is increased and memory space is wasted since no overprinting is implemented.

As shown in Fig. 10C, the blanking is performed using image data as shown in Fig. 10A and the image data line feed by 0.5 points as shown in Fig. 10B at the dot matrix printer to compensate for the deterioration in image quality , which is caused by the distance between mechanically formed vertical pressure pins. However, in the emulation method in a conventional page printer, the line segments are generated with the same thickness in every interval, and this means that the filling of empty spaces has no effect on the image quality and leads to an increase in the processing time.

An advantage of the invention is therefore the provision a method of saving space and shortening reduction in processing time for a page printer that does the job Tape buffer system used.

Another advantage of the invention is the provision a method for effectively achieving overprinting, filling in empty spaces, etc. when processing Data for use in a dot matrix printer of a page printer.

The invention is concerned with graphics processing proceed in a dot matrix printer with the following steps: Compare a previous graphic print type and a previous one position value of image data with a current graph phik print type or a current position value of image da ten; if the previous and the current graphic print type and the previous and current position values are the same, Set an overprint mark to "ON", and if so and the current position value are not the same and on Value obtained by subtracting the previous position value from the current position value is obtained within one Empty space filling area, performing an empty space Filling; Replace the current position value with the  previous position value if the value is not within the There is a void fill area or the void fill gang is complete and initialize a pin number;  and generating image data with respect to a corresponding one Pen, checking that the overwrite or overprint mark is set, overprinting of current image data via to previous image data with corresponding pen number if the Overprint mark is turned on, and inserting the current one Image data in the symbolic buffer when the overprint mark is not switched on.

Furthermore, the image data overprinting process has the following Steps on: Check whether the image data via the previous i image data can be printed, insert the current one Image data in the symbolic buffer if the image data is not can be overprinted and remove an element which ches through the previous image data with a corresponding Pin number can be specified, from the symbolic buffer, if the image data can be overprinted; Overprint the Image data of the removed element about the current image data and re-education of an element, which in the symbolic buffer to be inserted; and repatriation the removed element into a free memory area and Insert the newly formed element in the symbolic Buffer.

The invention is illustrated below with reference to drawings ter exemplary embodiments explained in more detail, from which further Advantages and features emerge. It shows:

Fig. 5 shows a method for forming print fonts from graphical image data in a dot matrix printer with 8 pens (needles);

Fig. 6 shows a scanning method for graphic image data for 8 pens in a page printer;

Fig. 7 is a method for forming line segments from the graphics image data for 8 pins;

Fig. 8 shows the configuration of a symbolic buffer;

Fig. 9 shows the form of graphic image data inputs in the case of overprinting in a dot matrix printer, as well as the outputs in the dot matrix printer and page printer obtained by the input graphic image data;

FIG. 10A to 10C, an example for the filling of voids in a dot matrix printer,

Fig. 1 is a block diagram of a general page printer to which the present invention is applied;

Figs. 2A to 2B, a flow chart of a series of steps for processing of overprinting and the filling of voids in a dot matrix printer for uses in a page printer, according to the vorlie constricting invention;

Fig. 3 is a flow chart of a sequence of steps for processing image data for overprinting of Fig. 2; and

FIGS. 4A to 4C, an example of the attachment of image data at the overpressure operation of FIG. 3.

In Fig. 1 an inserted with the present invention page printer system is shown, comprising a printing unit 713 for printing the image, a controller 700 for controlling the printing unit 713, and a computer 715 for transmission of different files to the controller 700. The controller 700 has a central processing unit (CPU) 701 for controlling the entire part, an interface 711 for communication with the printing unit 713 and the computer 715 via serial and parallel ports 771 and 772 , a keypad 707 , a display 705 and a memory 703 for storing data. The memory 703 is divided into a ROM in which program code is provided and a RAM in which data is stored when the system is in operation. The program code consists of a core part for the management of all resources of the controller 700 and an emulation program part for analyzing different printer control commands by using interface functions which are provided by the core part. In general, the core part is located in the ROM, and the emulation program part is provided in the form of a cartridge so as to meet the various printer commands and a user's requirements.

The emulation process for implementing image data for Use in the dot matrix printer for the page printer provides a filter function so that the effect overprinting, filling in empty spaces, etc. to be used, the image quality with the dot matrix to improve printers.

As shown in FIG. 2, the CPU 701 compares a previous graphics mode with a current graphics mode in a step 8 a. Because data is transferred to other farms, depending on the resolution of the image data in each printer, and particularly in the page printer, low resolution data is enlarged upon printing after it is compressed and stored when the graphics modes are not the same therefore overprinting is not implemented. In step 8, b is checked whether the Stiftnum mer PNO is the previous image data is equal to the pin number mo mentaner image data or not. If the pin numbers PNO are not identical, overprinting is not carried out. In step 8 c, a position value of previous image data AY is checked to determine whether it is the same value as the position value of current image data BY. If the position values are the same as one another, the process proceeds from step 8 c to step 8 e in order to set an overprint mark to the "ON" state. If the position values are not the same, the previous position value AY is subtracted from the current position value BY in order to obtain a value DY in step 8 d. In step 8 f it is checked whether the value DY lies between 0 and an empty space filling area ε or not. The area ε has different values depending on the head shape of the dot matrix printer, and the size is basically determined by half the distance between pins or needles of the head. In the case of a dot matrix printer with 9 needles, the distance between pens is, for example, 0.339 mm (1/75 '') and in this case a line feed of 0.169 mm (1/150 '') or less is used. If the value DY lies within the empty space filling area ε, a transition is made from step 8 f to step 8 g in order to carry out the filling of the empty space.

When raster image data of a line is printed in the side printer, the thickness of the image data (a Y-axis) is determined. In the conventional dot matrix printer emulation method, the thickness of a line or line is determined by the distance between pins of the head. For a 300 DPI (dots per inch) page printer, when the data is emulated for use with a 240 DPI dot matrix printer, the distance between the pens is 4.2 dots and one dot of the image data in the dot matrix printer is increased vertically by 5 points, corresponding to an integer value of 4.2 points. In step 8 g, the printing is carried out after feeding by half the distance between the pens of the dot matrix printer.

Therefore, the position of the previously processed graphic image data stored in the buffer chert, and even if the thickness of a corresponding line or line is reduced to 3 points when data is again be applied after a feed half the distance between the pins, the space can be up to next line or line. By the side printer using a tape buffer system can therefore Processing time is reduced and efficiency is increased.

In step 8 h before replacing the set position values take precedence AY, for use in a next scan, and the pin number PNO, which is used as an index of a pin, is an initialization value of 1, the current position value of BY. Then, generated in step 8 i an image data value for a corresponding pin. While the image data is being scanned in the dot matrix printer, line segments are created by connecting adjacent dots together and the line segments are appended to the buffer in which image data is stored. In the next step 8 j it is checked whether the overpressure mark is set to "ON" or not. If the overprint mark is in the "ON" state, step 8 j continues with step 8 l in order to overprint the image data with the current image data which are inserted into a current line or line. The overprinting process will be described with reference to the flow chart of FIG. 3. If the overprint mark is in the "OFF" state, the current image data are inserted into the symbolic buffer in step 8 k, and at the same time the inserted position is stored in the printer buffer in which the previous image data were stored, so that next line or line operation to be used. Then in step 8 m it is checked whether all the pins have been processed or not. Were not all the pins have been processed, following the step 8 Step 8 m of n to the pins number PNO to increase. 1

As is apparent from Fig. 3, in step 9 a through Überprü evaporation of DPI of the saved image data to check whether overprinted with the current image data to previous image data who can or not. When overprinting can take place, so an 8 gespeicher th element in step 9 b eliminated in the symbolic buffer of Fig., Using the previous image data (the eliminated element is referred to as a first element). In this case the first element is only eliminated from the symbolic buffer and remains in the memory. Furthermore, the elimination method is similar to the method for eliminating an element from the linked list. The image data of the eliminated element and the current image data are printed in step 9 c, as shown in FIG. 4A to 4C. FIGS. 4A to 4C show examples of the current image data, the previous image data or the overprinted image data. In FIGS. 4A to 4C X denotes a point. In step 9, d is a second element which is to be inserted in the symbolic buffer formed by a renaming process for various para meters for the image data obtained in step c. 9 In the case of a page printer with 300 DPI, since image data is compressed to half with 150 DPI, the start position of an X axis of the current image data and the previous image data coincide with the bit position which corresponds to half the start position of the current image data speaks. When this image data is overprinted, the image data shown in Fig. 4C is obtained, and the start position of an X axis of the overprinted image data is determined by a small value between the start positions of the two image data. Furthermore, the width is determined by the difference between the larger byte value of the final positions of the two image data and the byte values of the start position of the overprinted image data. In step 9 e, a solution process is carried out in order to return the previous image data to a free memory area of the system. In step 9 f, the second element is inserted again in the symbolic buffer. If meanwhile the current image data and the previous image data cannot be overprinted in step 9 a, the current image data are inserted into the symbolic buffer in step 9 g.

As described above, the dot matrix printing Emulation process for the page printer that uses the tape buffer system uses, shorten processing time and memory save space by effectively achieving the overprinting of the Filling in blank spaces, etc., usually at the point matrix printers are used.

Claims (4)

1. A graphic emulation method for a page printer using a tape buffer system such that line segments are stored in a symbolic buffer, whereby image data to be used in a dot matrix printer are converted, with the following steps:

• a) performing a first comparison ( 8 a) between a previous graphic print type and a current graphic print type and performing a second comparison ( 8 b) between a pen number of previous image data and a pen number of current image data;
• b) performing a third comparison ( 8 c) between a first position value (AY) of the previous image data and a second position value (BY) of the current image data if the previous graphic print type is equal to the current graphic print type and the pen number of the previous one Image data is the same as the pen number of the current image data.
• c) setting ( 8 e) an overprint mark to a first state when the first position value is equal to the second position value as a result of the third comparison ( 8 c);
• d) subtracting ( 8 d) the first position value (AY) from the second position value (BY) to obtain a difference value (DY) if the first position value (AY) is not equal to the second position value (BY), check ( 8 f) whether the difference value (DY) is less than a predetermined void fill area (ε), and executing a void fill function ( 8 g) if the difference value (DY) is less than the predetermined void fill area (ε ) is;
• e) setting ( 8 h) the second position value (BY) equal to the first position value (AY), and
• f) generating ( 8 i) new image data for a corresponding pen, checking ( 8 j) whether the overprint mark is set to the first state, overprinting ( 8 l) the current image data on a corresponding pen number if the overprint mark is set to the first state, and inserting ( 8 k) the current image data into the symbolic buffer when the overprint mark is set to a second state.

2. Emulation method according to claim 1, characterized net that the symbolic buffer from a variety of under linked lists is formed. 3. Emulation method according to claim 1 or 2, characterized indicates that the void fill area (ε) is essentially half the distance between two pins of a head of the Dot matrix printer is selected. 4. Emulation method according to one of claims 1 to 3, in which step (f) further comprises the following steps:
Checking ( 9 a) whether the previous image data can be overprinted by the image data, inserting ( 9 g) the current image data into the symbolic buffer if the image data cannot be overprinted, and removing ( 9 b) an element, which was designated by the previous image data with a corresponding pen number, from the symbolic buffer if the image data can be overprinted;
Overprint (9 c) of the image data of the remote element with the current image data and reforming a further element which is to be inserted in the symbolic buffer; and
Returning ( 9 e) the removed element to a free memory area and inserting the transformed element in the symbolic buffer.